GB2065696A

GB2065696A - Process for the coking quality of coals having unsatisfactory properties

Info

Publication number: GB2065696A
Application number: GB8037466A
Authority: GB
Original assignee: Ruetgerswerke AG
Current assignee: Ruetgers Germany GmbH
Priority date: 1979-12-19
Filing date: 1980-11-21
Publication date: 1981-07-01
Also published as: FR2473055B1; PL133181B1; PL228575A1; CS219298B2; FR2473055A1; JPS5945710B2; JPS5693791A; DE2951116A1; AU6552580A; GB2065696B; US4380454A; AU538088B2; DE2951116C2; ZA807052B

Description

1 GB 2 065 696 A 1

SPECIFICATION

A process for improving the coking quality of coals having unsatisfactory coking properties The invention relates to the use of pitch-like coal by-products to improve the coking properties of coals, especially the coking properties of coals with an unsatisfactory coking behaviour.

Metallurgical coke, which is produced by coking suitable types of coal in a horizontal chamber oven, is used as an essential raw material in the production of pig iron. However, metallurgical coke can only be produced from a limited number of types of coal. These coals are described in the International Coal Classification by the sequence of digits 433 and 434, and have a volatiles content of between 24 and 28%.

World-wide, the proportion of first-class coking coal is however only about 5% of the coal 10 reserves, though a further 15% is limitedly cokable without pretreatment. In practice, therefore, mixtures of higher volatile content coals and lean coals have been used for a long time to achieve optimum coking properties.

However, the use of coal mixtures does not in every case guarantee an optimum coking behaviour and a good quality of the resulting coke. If for example, the Roga caking index is insufficient, the 15 resulting coke has too high an abrasion (Micum drum strength MJ or too, low a lumpiness (Micum value M3. or M4d' On account of the continuing high demand for metallurgical coke in the future, it will be necessary by means of suitable additives or processes to make cokable the predominantly occurring coals having poor coking behaviour, thereby making it possible to use other types of coal in addition to the conventional coking coals for producing metallurgical coke.

In addition to thermal and mechanical pretreatment of coals (prior heating and/or compaction operations), petroleum-based and coal-based bituminous materials have in particular been proposed in the past as improvement agents to obtain an improved coking behaviour (see K.-G.Beck, 1. Meckel, Gluckaul 115 (1979) p. 979/83).

Thus, for example, German Offen leg u ngssch rift 2 643 519 describes a process according to which a pitch is produced from a heavy petroleum fraction by thermal and chemical aromatisation, with which the coal to be improved can be converted into good meta;;urgical coke. The disadvantage of the method however is that the petroleum residue cannot be directly used as an improvement agent, but instead has to be converted by an environmentally harmful and heat-intensive process into a suitable additive. 30 The use of a coal-based improvement agent is described in U.K. Patent Specification 1 528 546.

In this process a coal extract produced from anthracene oil and coal is recommended as a coking coal improvement agent. The disadvantage of this process however is that the economic operation appropriate to large-scale demand is very limited on account of the preferred use of anthracene oil as a chemical raw material for producing high-grade dyestuff intermediates. Coal-tar pitch, which is successfully used as a coking coat improvement agent (see the first- mentioned reference), is likewise available only to a limited extent for this purpose since because it is a high-grade, low-ash raw material, it is preferentially used to produce pure carbon products.

German Offen leg u ngssch rift 2 164 474 describes a process in which bituminous coking coal improvement agents such as coal-tar, petroleum distillation residues or petroleum-based extraction 40 residues are used in amounts of 1-40% by weight as coking coal improvement agents. The disadvantage of this procedure is that for a coking coal improvement of this p.-ocedure is that for a coking coal improvement agent, the only slightly aromatised petroleum- based material first has to be subjected to a costly thermal aromatisation, while the afore-mentioned restriction applies in respect of the coal-tar based products.

On account of the afore-mentioned scarcity of suitable coking coals and the described disadvantages of the hitherto proposed coking coal improvement agents, there is an immediate need to find coal additives which do not have the afore-mentioned disadvantages and which are equivalent as regards the recognised good improvement properties of coal-tar pitch.

It was therefore an object of the present invention to find such a coking coal improvement agent in 50 order to be able to upgrade coals with unsatisfactory coking properties for use in the production of metallurgical coke in coking ovens.

According to the invention, this objective can be achieved by using a coking coal improvement agent which is obtained by distilling off 2 to 20% of light boiling constituents from the high aromatic content, pitch-like coal by-product obtained by disintegrating comminuted coal and/or similar carbonaceous raw materials with a mixture of coal- based and petroleum-based hydrocarbons as solvents using elevated temperature and pressure conditions. The pitch-like product obtained after the distillation has a softening point (Kramer-Sarnow) of 90 to 1 601C and in accordance with the invention is mixed in an amount of 1 to 20% by weight, preferably 3 to 12% by weight, with a coal or coal mixture 60 having unsatisfactory coking properties, and coked in a high temperature oven.

The production of high aromatic content coal by-products is the subject of our earlier patent application entitled "Process for preparing highly aromatic pitch-like hydrocarbons" and which claimed priority of 30 August 1979 from W. German Patent Application No. P2935039.8. The reader is now referred to the specification of that earlier patent application. Briefly, the process involves disintegrating

2 GB 2 065 696 A 2 coal with a solvent comprising an aromatised residue obtained from the steam pyrolysis of a petroleum fraction and a complementary solvent comprising a coal-based aromatic mixture having an average boiling point above 35011C, and optionally with the addition of further solvent. Preferably 10 to 15% of higher boiling fractions are distilled off. The softening point of the pitch-like product thus produced of 90 5 to 1 601C is essentially determined by the degree of removal of these lighter boiling substances.

The coal by-product used according to the invention for the improvement can, when using coal mixtures, either be added separately to one of the coals, or can be added after the coals have been mixed. The good granulation behaviour and storage behaviour of the coking coal improvement agent according to the invention has proved to be of particular advantage, which makes it possible for the agent to be added in both solid and liquid form. The coking coal additive according to the invention 10 corresponds in this respect to the coal-tar pitch recommended for coking coal improvement.

The production of coking coal improvement agents according to the invention and their use is described in the following non-limiting Examples 1 to 3. Comparison Examples 4 and 5 are also given.

The coking coal mixture to be improved was a mixture of 70% of a high volatiles coal (37% volatiles, water and ash-free, International Classification No. 632) and 30% of a lean coal (19% 1 volatiles, International Classification No. 332).

The coal mixture was coked for 5 hours at 1 0001C in a 7 kg experimental coking oven with 4 and 8% of additive. The coke produced was subjected to the standardised Micurn drum tests to determine the M1. and M3. values.

The ensuing Table gives the values for the lumpiness (MA and the abrasion W,,J of the coke 20 prcduced by adding the improvement agent according to the invention.

A corresnonding coking coal mixture without any additive, and a similar coking coal mixture to which 15% of'coal extract based on anthracene oil had been added for improvement purposes according to U.K. Patent Specification 1 528 546, were taken for comparison. The coke to be compared was in each case obtained under comparable conditions both as regar& coking apparatus and 25 temperature and time conditions.

EXAMPLE 1

Corresponding to the method described in our said earlier patent application, a pitch-like coal by- product was produced by disintegrating 30 parts by weight of open burning coal (International Classification Number 611, Westerholt type, Ruhr) with 35 parts by weight of pyrolysis residue obtained 30 from cracking crude petroleum, 10 parts by weight of pitch distillate from the flash distillation of coaltar pitch, and 25 parts by weight of pitch distillate from the heal/pressure treatment of coal-tar pitch. The mixture was subjected to a reaction temperature of 3701C, a maximum pressure of 30 bars, and a reaction time of 3 hours.

35. 15 parts by weight of the pitch obtained in this way was topped (that is, distilled off). The coal by- 35 product thus obtained was characterised by the following data: softening point (Kramer-Sarnow) 1091C; sulphur: 0.6%; ash 2.7%; proportion insoluble in quinoline: 10.4%.

This coal by-product was added in a proportion of 4% by weight to the above-specified coking coal mixture to be improved, consisting of 70% by weight of high volatiles coal and 30% by weight of lean coal, and the mixture coked in the 7 kg capacity experimental oven at 1 00011C for a coking time of 5 40 hours. The quality of the coke obtained can be seen in the Table.

EXAMPLE 2

The procedure of Example 1 was followed. However, as coking coal improvement agent, 8% by weight of coal by-product obtained as described in Example 1 was added to the coking coal mixture of the above-described specification. The quality of the coke obtained can be seen from the Table. 45

EXAMPLE 3

The procedure of Example 1 was followed, but however the following solvent mixture was used for the disintegration: 35 parts by weight of pyrolysis residue from the cracking of gas oil, 25 parts by weight of pitch distillate from the heat/pressure treatment of coal-tar pitch and 10 parts by weight of filtered anthracene oil (cf. H,G. Franck, G.Collin, Steinkohlenteer, Berlin 1968, page 57).

By topping 12 parts by weight, a coal by-product having a softening point of 11 311C was obtained.

Further characteristic data are: sulfur: 1.9% ash 2.8%; fraction insoluble in quinoline: 10.2%.

This coal by-product was added in a proportion of 8% by weight to the coking coal mixture to be improved consisting of 70% of a high volatiles coal (37% volatiles, water- and ash-free, International Classification Number 632) and 30% of a lean coal (19% volatiles, International Classification Number 55 332), and the mixture coked under the same conditions as in Example 1. The coking quality can be seen from the Table.

z d 3 GB 2 065 696 A 3 TABLE

Micurn indices of the coke produced Example Oven batch M10 M30 1 Coal mixture of the specif led type with 10 80 4% coal by-product according to Example 1 2 Coal mixture of the specified type with 10 82 8% coal by-product according to Example 1 3 Coal mixture of the specif led type with 10 88 8% coal by-product according to Example 2 4 Coal mixture of the specified type without 11.5 78 additive Coal mixture corresponding to the specifica- 11 83 tion according to UK Patent Specification

1 528 546 with an addition of 15% coal extract (anthracene oil) 1 It will be seen that the cokes produced by Examples 1 to 3 of the invention have lower (that is, better) M1. values and higher (that is, better) IVI,, values than are obtained when no improvement additive is employed (Example 4). The coke of Example 5 has a marginally better M.. value, but one has to bear in mind the previously mentioned facts which militate against the use of anthracene oil in accordance with the U.K. patent specification No. 1 528 546.

Claims

1. A process for improving the coking quality of a coal, wherein a pitchlike product having a softening point (Kramer-Sarnow) of 30 to 1601C and prepared by distilling off between 2 and 20% of the light boiling constituents from a high aromatic content coal by- product itself obtained by disintegrating comminuted coal and/or similar carbonaceous raw material with a mixture of coal-based and petroleum-based hydrocarbons as solvent, using elevated temperature and pressure conditions, is mixed in a proportion of 1 to 20% by weight with coal and the mixture is coked.

2. A process according to claim 1, wherein the coal by-product is obtained by disintegrating coal or other carbonaceous materials with a solvent comprising an aromatic residue obtained from the steam 15 pyrolysis of a petroleum fraction and a complementary solvent comprising a coal-based aromatic mixture having an average boiling point above 3500C, using a pressure of up to 50 bars and a temperature of between 250 and 4201C.

3. A process according to claim 2, wherein the mixture of the solvent and complementary solvent contains one or more further solvents.

4. A process according to claim 1, 2 or 3, wherein 3 to 12% by weight of the pitch-like product is mixed with the coal before the coking.

5. A process according to any preceding claim, wherein from 10 to 15% of light volatile constituents is distilled from the coal by-product to obtain the pitch- like product.

6. A process for improving the coking quality of a coal, the process being substantially as described in any of the Examples 1, 2 or 3.

7. Coke made by a process according to any of claims 1 to 6.

8. Pig iron made using a coke of claim 7 as a raw material.

Printed for Her Majesty's Stationery Office by the Courier Press, Leamington Spa, 1981. Published by the Patent Office, Southampton Buildings, London, WC2A lAY, from which copies may be obtained.